When selecting a heater for tank heating application you must first determine whether the application requires that the temperature be maintained or if the temperature needs to be raised. Below are the calculations for each application. You can also visit our website and utilize our online calculator; look for the free calculator link near the top of the page.

Maintain Temperature

To calculate the KW required to maintain the temperature of a tank you will need to determine the tanks surface area, process temperature to be maintained, minimum ambient temperature and the R-value of the insulation.

Surface area:

Round tank –

A (ft²) = (2 x p x r x h) + (2 x p x r²)

p = 3.14

r = radius (ft)

h = height (ft)

Rectangular tank –

A (ft²) = 2 x [(l x w) + (l x h) + h x w)]

l = length (ft)

w = width (ft)

h = height (ft)

After determining the tanks surface area the maintain KW can be calculated as follows:

KW = (A x (1/R) x ΔT(°F) x SF)/3412

A = surface area

R = R-value of the insulation

Use 0.5 as the R-value of an uninsulated steel tank

See the chart below for typical examples

R-value = thickness (in.)/k-factor

ΔT = difference between the process set point temperature and lowest ambient temperature

SF = safety factor, recommended 1.2

3412 = conversion of BTU to KW

Table 1

Insulation Type

R-Value/inch of thickness

Fiberglass

R-3

Mineral fiber

R-3.7

Calcium silicate

R-2

Open-cell polyurethane foam

R-3.6

Closed-cell polyurethane foam

R-6

Polyisocyanurate spray foam

R-6

Example:

A 42’ diameter x 40’ tall crude oil tank with R-6 insulation needs to be maintained at 75°F given a minimum ambient temperature of 10°F.

A = (2 x 3.14 x 21 x 40) + (2 x 3.14 x 21²)

A = 8044.68 ft²

KW = (8044.68 x 1/6 x 65 x 1.2)/3412

KW = 30.65

Raise Temperature

The KW calculation to raise the temperature of a material in a tank (heat-up) starts with the same information required in the maintain application. Additionally we’ll need the weight of the material to be heated, the specific heat of the material and the time required to heat the material from its start temperature to its end temperature. The KW calculation to raise the temperature is as follows:

KWtotal = KWheat-up + KWmaintain

KWheat-up = [(M x Cp x ΔT x SF)/3412]/t

M = weight of the material in pounds

Cp = Specific Heat, see examples in the chart

ΔT = difference between the process set point (end) temperature and the start temperature

SF = safety factor, recommended 1.2

3412 = conversion of BTU to KW

t = time in hours

KWmaintain = (A x (1/R) x ΔT(°F) x SF)/3412

A = surface area

R = R-value of the insulation

Use 0.5 as the R-value of an uninsulated steel tank

ΔT = difference between the process set point temperature and lowest ambient temperature

SF = safety factor, recommended 1.2

3412 = conversion of BTU to KW

Example:

A 4’ x 6’ x 12’ tank with 1800 gallons of water needs to be heated from 60°F to 95°F in 3 hours. The tank has R-4 insulation and the minimum ambient temperature is 0°F.

To begin we need to convert the gallons of water to pounds:

lbs = G x D1

G = gallons

D1 = lbs per gallon from the chart below

lbs = 1800 x 8.34

lbs = 15,012

If the volume of the tank is stated in cubic feet (ft³) the formula looks like this:

lbs = C x D2

C = Cubic feet of material

D2 = lbs per ft³ from the chart below

Table 2

Material

D1

lbs/gallon

D2

lbs/ft³

Specific Heat

water

8.34

62.4

1

#1 fuel oil

6.8

50.5

0.47

#2 fuel oil

7.2

53.9

0.44

#3,4 fuel oil

7.5

55.7

0.425

#5,6 fuel oil

7.9

58.9

0.41

Bunker C

8.15

61

0.5

SAE 10-50 weight oil

7.4

55.4

0.43

ethylene glycol

9.4

70

0.55

50% ethylene glycol/water

8.8

65.8

0.76

air

–

0.073

0.24

nitrogen

–

0.073

0.25

KWheat-up = [(15,012 x 1 x 35 x 1.2)/3412]/3

KWheat-up = 61.6

plus

KWmaintain = (288 x 1/4 x 95 x 1.2)/3412

KWmaintain = 2.4

KWtotal = 64

Calculations for heating air in a duct

Once the volume of air in standard cubic feet per minute (SCFM) and the required temperature rise in °F (ΔT) are known, the required kilowatt rating (KW) of the heater can be determined from the following formula:

KW = (SCFM x ΔT)/3193

Note that CFM is given at standard conditions (SCFM): 80° F and normal atmospheric pressure of 15 psi. The CFM at a higher pressure (P) and inlet air temperature (T) may be calculated as follows:

SCFM = ACFM x (P/15) x [540/(T+460)]

Example:

A drying oven, operating at 25 psia (10 psi gauge pressure), recirculates 3000 CFM of air per minute through a heater which raises its temperature from 350 to 400° F.

To select an appropriate heater:

Step 1: Convert 3000 CFM at 25 psia and 350° F to CFM at standard conditions using the above formula:

3000 x (25/15) x [540/(350°F+460)] = 3333 SCFM

Step 2: Calculate the required KW:

[3333 SCFM x (400°F-350°F)]/3193 = 52 KW

Calculations for circulation heater applications

When calculating the power required to heat a material flowing through a circulation heater, the KW equation shown below can be applied. This equation is based on the criteria that there is no vaporization occurring in the heater. The KW equation incorporates a 20% safety factor, allowing for heat losses of the jacket and piping, variation in voltage and wattage tolerance of the elements.

We have 8GPM of water with an inlet temperature of 65°F and outlet temperature of 95°F. First, convert the flow rate to lbs/hr.

8 gal

x

1 ft³

x

60 min

=

64.17 ft³/hr

min

7.48 Gal

1 hr

Convert to lbs/hr, obtain the density and specific heat from table 2 above.

64.17 ft³/hr x 62.4 lbs/ft³ = 4004 lbs/hr

Now calculate the KW:

KW

=

4004 lbs/hr x (95-65)°F x 1 BTU/lb °F x 1.2

3412

KW

=

42

Gas heating example:

Air is flowing at 187 CFM and 5 PSIG pressure. It needs to be heated from an inlet temperature of 90°F to an outlet temperature of 250°F. First, convert the flow rate to SCFM using the formula given earlier.

187 x (20/15) x [540/(90°F+460)] = 243.7 SCFM

Convert to lbs/hr, again referring to table 2 for the density and specific heat.

243.7 SFCM

x

60 min

x

0.073 lbs

=

1067.4 lbs/hr

1 hr

ft³

Now calculate the KW:

KW

=

1067.4 lbs/hr x (250-90)°F x 0.24 BTU/lb °F x 1.2

3412

KW

=

14.4

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Our heaters are currently UL recognized, CSA compliant and CE approved. We are ASME and National Board certified for Section VIII Div 1 Pressure Vessel Welding.
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